悩んでること
PythonとTensorFlowで点群データを分類するコードを下記ページを参考に作成しました。
10個ほどの異なる点群をインプットして実行すると、すべてが同じ分類を返されてしまいます。
コードにどんな改良を加えれば良いでしょうか?
参考URL
https://tensorflow.classcat.com/2021/12/06/keras-2-examples-vision-pointnet/
環境
Windows10
Python 3.9.15
TensorFlow 2.11.0(GPUは使用せずCPUで実行)
Keras 2.11.0
コード
下記コードの実行上の注意点:
learn関数の第2引数をFalseでデータを訓練し、predict関数で点群を与え分類を判定してます。
import os
import glob
import trimesh
import numpy as np
import tensorflow as tf
from tensorflow import keras
from keras import layers
import json
import random
class pointNet_tf2:
BATCH_SIZE = 32
NUM_CLASSES = 3
NUM_POINTS = 2048
NUM_X = 16
NUM_Y = 16
NUM_Z = 8
#NUM_X * NUM_Y * NUM_Z = NUM_POINTSであること!!
DATASET_DIR = 'core\\pointNet\\Datasets'
# MODEL_FILE = 'ModelNet40_model.json'
# WEIGHT_FILE = 'ModelNet40_weight.h5'
MODEL_FILE = 'ModelNet40_model.keras'
CLASS_FILE = 'ModelNet40_class.json'
def parse_dataset(self, data_set_dir, num_points):
train_points = []
train_labels = []
test_points = []
test_labels = []
class_map = {}
folders = glob.glob(os.path.join(data_set_dir, "[!README]*"))
for i, folder in enumerate(folders):
print("processing class: {}".format(os.path.basename(folder)))
# store folder name with ID so we can retrieve later
class_map[i] = os.path.basename(folder)
# gather all files
train_files = glob.glob(os.path.join(folder, "train/*"))
test_files = glob.glob(os.path.join(folder, "test/*"))
for f in train_files:
train_points.append(trimesh.load(f).sample(num_points))
train_labels.append(i)
for f in test_files:
test_points.append(trimesh.load(f).sample(num_points))
test_labels.append(i)
return (
np.array(train_points),
np.array(test_points),
np.array(train_labels),
np.array(test_labels),
class_map,
)
def augment(self, points, label):
# jitter points
points += tf.random.uniform(points.shape, -0.005, 0.005, dtype=tf.float64)
# shuffle points
points = tf.random.shuffle(points)
return points, label
def conv_bn(self, x, filters):
x = layers.Conv1D(filters, kernel_size=1, padding="valid")(x)
x = layers.BatchNormalization(momentum=0.0)(x)
return layers.Activation("relu")(x)
def dense_bn(self, x, filters):
x = layers.Dense(filters)(x)
x = layers.BatchNormalization(momentum=0.0)(x)
return layers.Activation("relu")(x)
class OrthogonalRegularizer(keras.regularizers.Regularizer):
def __init__(self, num_rows, num_cols, l2reg=0.001, **kwargs):
self.num_features = num_rows
self.l2reg = l2reg
self.num_rows = num_rows
self.num_cols = num_cols
self.eye = tf.eye(num_rows, num_cols)
def __call__(self, x):
x = tf.reshape(x, (-1, self.num_features, self.num_features))
xxt = tf.tensordot(x, x, axes=(2, 2))
xxt = tf.reshape(xxt, (-1, self.num_features, self.num_features))
return tf.reduce_sum(self.l2reg * tf.square(xxt - self.eye))
def get_config(self):
config = {
'num_rows': self.num_rows,
'num_cols': self.num_cols
}
return dict(list(config.items()))
def tnet(self, inputs, num_features):
# Initalise bias as the indentity matrix
bias = keras.initializers.Constant(np.eye(num_features).flatten())
reg = self.OrthogonalRegularizer(num_features, num_features)
x = self.conv_bn(inputs, 32)
x = self.conv_bn(x, 64)
x = self.conv_bn(x, 512)
x = layers.GlobalMaxPooling1D()(x)
x = self.dense_bn(x, 256)
x = self.dense_bn(x, 128)
x = layers.Dense(
num_features * num_features,
kernel_initializer="zeros",
bias_initializer=bias,
activity_regularizer=reg,
)(x)
feat_T = layers.Reshape((num_features, num_features))(x)
# Apply affine transformation to input features
return layers.Dot(axes=(2, 1))([inputs, feat_T])
# コンストラクタ
def __init__(self):
tf.random.set_seed(1234)
self.classes = None
inputs = keras.Input(shape=(self.NUM_POINTS, 3))
x = self.tnet(inputs, 3)
x = self.conv_bn(x, 32)
x = self.conv_bn(x, 32)
x = self.tnet(x, 32)
x = self.conv_bn(x, 32)
x = self.conv_bn(x, 64)
x = self.conv_bn(x, 512)
x = layers.GlobalMaxPooling1D()(x)
x = self.dense_bn(x, 256)
x = layers.Dropout(0.3)(x)
x = self.dense_bn(x, 128)
x = layers.Dropout(0.3)(x)
outputs = layers.Dense(self.NUM_CLASSES, activation="softmax")(x)
self.model = keras.Model(inputs=inputs, outputs=outputs, name="pointnet")
self.model.summary()
self.model.compile(
loss="sparse_categorical_crossentropy",
optimizer=keras.optimizers.Adam(learning_rate=0.001),
metrics=["sparse_categorical_accuracy"],
)
# 学習、訓練
def learn(self, root_dir, save):
# データセットのロード
# data_set_dir = tf.keras.utils.get_file(
# "modelnet.zip",
# "http://3dvision.princeton.edu/projects/2014/3DShapeNets/ModelNet40.zip",
# extract=True,
# )
# data_set_dir = os.path.join(os.path.dirname(data_set_dir), "ModelNet40")
data_set_dir = os.path.join(root_dir, self.DATASET_DIR)
# mesh = trimesh.load(os.path.join(data_set_dir, "chair/train/chair_0001.off"))
# mesh.show()
# points = mesh.sample(NUM_POINTS)
# fig = plt.figure(figsize=(5, 5))
# ax = fig.add_subplot(111, projection="3d")
# ax.scatter(points[:, 0], points[:, 1], points[:, 2])
# ax.set_axis_off()
# plt.show()
# データセットのパース
train_points, test_points, train_labels, test_labels, class_map = \
self.parse_dataset(data_set_dir + '\\ModelNet40', self.NUM_POINTS)
self.classes = class_map
# データセットの増強
train_dataset = tf.data.Dataset.from_tensor_slices((train_points, train_labels))
test_dataset = tf.data.Dataset.from_tensor_slices((test_points, test_labels))
train_dataset = train_dataset.shuffle(len(train_points)).map(self.augment).batch(self.BATCH_SIZE)
test_dataset = test_dataset.shuffle(len(test_points)).batch(self.BATCH_SIZE)
# モデルの訓練
self.model.fit(train_dataset, epochs=20, validation_data=test_dataset)
# テスト
num_test = 10
test_data = test_dataset.take(1)
points, labels = list(test_data)[0]
points = points[: num_test, ...]
labels = labels[: num_test, ...]
for t in range(num_test):
print("pred test[" + str(t) + "]:answer=" + self.classes[labels.numpy()[t]] + ",pred=" + self.predict(points[t]))
if (save):
# 保存
keras.models.save_model(self.model, data_set_dir + '\\' + self.MODEL_FILE)
# self.model.save_weights(data_set_dir + '\\' + self.WEIGHT_FILE)
with open(data_set_dir + '\\' + self.CLASS_FILE, 'wt') as f:
json.dump(class_map, f, ensure_ascii=False, indent=4, sort_keys=True, separators=(',', ': '))
# 学習済みデータのロード
def load(self, root_dir):
data_set_dir = os.path.join(root_dir, self.DATASET_DIR)
# self.model = keras.models.load_model(filepath=data_set_dir + '\\' + self.MODEL_FILE,
# custom_objects={"OrthogonalRegularizer": pointNet.OrthogonalRegularizer})
self.model = keras.models.load_model(filepath=data_set_dir + '\\' + self.MODEL_FILE)
# self.model.load_weights(data_set_dir + '\\' + self.WEIGHT_FILE)
self.classes = {}
with open(data_set_dir + '\\' + self.CLASS_FILE) as f:
work = json.load(f)
for k,v in work.items():
self.classes[int(k)] = v
#アップサンプリング
def upSampling(self, points):
ret = []
if len(points) > 0:
while(len(ret) < self.NUM_POINTS):
ret.append(points[0])
return ret
#ダウンサンプリング
def downSampling(self, points):
ret = []
# 各次元の最小値と最大値を取得する
x_min = None
x_max = None
y_min = None
y_max = None
z_min = None
z_max = None
for p in points:
if ((x_min is None) or (x_min > p[0])):
x_min = p[0]
if ((x_max is None) or (x_max < p[0])):
x_max = p[0]
if ((y_min is None) or (y_min > p[1])):
y_min = p[1]
if ((y_max is None) or (y_max < p[1])):
y_max = p[1]
if ((z_min is None) or (z_min > p[2])):
z_min = p[2]
if ((z_max is None) or (z_max < p[2])):
z_max = p[2]
# パラメータをワーク領域にコピーする
x_size = (x_max - x_min) / self.NUM_X
y_size = (y_max - y_min) / self.NUM_Y
z_size = (z_max - z_min) / self.NUM_Z
dim3 = [[[[] for z in range(self.NUM_Z)] for y in range(self.NUM_Y)] for x in range(self.NUM_X)]
for p in points:
x = int((p[0] - x_min) / x_size)
if x == self.NUM_X:
x = self.NUM_X - 1
y = int((p[1] - y_min) / y_size)
if y == self.NUM_Y:
y = self.NUM_Y - 1
z = int((p[2] - z_min) / z_size)
if z == self.NUM_Z:
z = self.NUM_Z - 1
dim3[x][y][z].append(p)
# ワーク領域からランダムに点を抽出する
while len(ret) != self.NUM_POINTS:
for x in range(self.NUM_X):
for y in range(self.NUM_Y):
for z in range(self.NUM_Z):
count = len(dim3[x][y][z])
if (count > 0):
idx = random.randint(0, count - 1)
ret.append(dim3[x][y][z].pop(idx))
if (len(ret) == self.NUM_POINTS):
break
if (len(ret) == self.NUM_POINTS):
break
if (len(ret) == self.NUM_POINTS):
break
return ret
# 予測、推論
def predict(self, points_input):
if (self.classes is None):
return 'error(モデルが不十分)'
sample = points_input
if (len(sample) == self.NUM_POINTS):
pass
elif (len(sample) < self.NUM_POINTS):
# アップサンプリング
sample = self.upSampling(sample)
else:
# ダウンサンプリング
sample = self.downSampling(sample)
if (len(sample) != self.NUM_POINTS):
return "error(点数が不正)"
points_output = tf.reshape(tf.convert_to_tensor(sample, dtype=np.float64), shape=(1, self.NUM_POINTS, 3))
preds = self.model.predict(points_output)
indexs = tf.math.argmax(preds, axis=1).numpy()
class_name = ''
for i in indexs:
class_name += self.classes[i] + ','
if (class_name == ''):
class_name = 'error(分類不明)'
else:
class_name = class_name[: len(class_name) - 1]
return class_name